Yes, IMHO.jegues said:So this is the design I should be aiming for in order to obtain the best consistent signal?
The optimum design is probably a ~100-turn primary coil and two symmetric ~50 turn bucking pickup coils. The ideal location is with each pickup coil probably centered over each end of the excited coil, to maximally intercept the dipole field from a conducting (or magnetic) ball. This would require some electrostatic shielding between the excited and pickup coils, however, so probably starting out with Mike's end-to-end coil layout in coil-3.jpg is best. I suspect that the excitation frequency will be in the 20 kHz range. The optimum frequency will be when the skin depth is ~equal to the radius of the balls. If it is too high, you will not be able to discriminate between aluminum and steel balls, for example. Do you know whether the excitation is pulsed or CW?Mike_In_Plano said:If your coils are off, you can scoot them closer or further with your thumb nail until you get a null. Or, you can use the orthogonal coil. I gaurantees a null simply by scooting it from left to right.
Bob S said:The optimum design is probably a ~100-turn primary coil and two symmetric ~50 turn bucking pickup coils. The ideal location is with each pickup coil probably centered over each end of the excited coil, to maximally intercept the dipole field from a conducting (or magnetic) ball. This would require some electrostatic shielding between the excited and pickup coils, however, so probably starting out with Mike's end-to-end coil layout in coil-3.jpg is best. I suspect that the excitation frequency will be in the 20 kHz range. The optimum frequency will be when the skin depth is ~equal to the radius of the balls. If it is too high, you will not be able to discriminate between aluminum and steel balls, for example. Do you know whether the excitation is pulsed or CW?
Bob S.